Class 12 Physics

Chapter 3 — Current Electricity

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Overview

Summary

NCERT Class 12 Physics Chapter 3, Current Electricity, covers the flow of electric charges through conductors, Ohm's law (V = RI), resistivity, drift velocity of electrons, Kirchhoff's rules, and circuit analysis tools such as the Wheatstone bridge.

Chapter 3 of NCERT Class 12 Physics Part I introduces the fundamentals of steady electric current. It explains how moving charges constitute current (I = Q/t), how free electrons in metallic conductors drift under an applied electric field, and derives Ohm's law (V = RI) from first principles. The chapter covers resistivity and its temperature dependence, electrical power dissipation (P = IV = I²R = V²/R), EMF and internal resistance of cells, series and parallel combinations of cells, Kirchhoff's junction and loop rules, and the Wheatstone bridge as a method for measuring unknown resistances.

Essentials

Key points & formulas

  1. 01Electric current is defined as the net charge flowing per unit time across a cross-section: I = Q/t (steady) or I = lim(ΔQ/Δt) as Δt→0 (instantaneous).
  2. 02Ohm's law states V = RI, where resistance R = ρl/A; resistivity ρ depends on material and temperature but not on the conductor's dimensions.
  3. 03Drift velocity of electrons under an electric field E is vd = –eEτ/m, where τ is the relaxation (average collision) time, giving conductivity σ = ne²τ/m.
  4. 04Resistivity of metals increases with temperature (ρT = ρ0[1 + α(T – T0)]), while resistivity of semiconductors decreases with increasing temperature.
  5. 05For a cell of EMF ε and internal resistance r connected to external resistance R, current I = ε/(R + r) and terminal voltage V = ε – Ir.
  6. 06Kirchhoff's rules — Junction Rule (sum of currents entering a junction equals sum leaving) and Loop Rule (algebraic sum of potential changes around any closed loop is zero) — enable analysis of complex circuits; the Wheatstone bridge balance condition is R1/R2 = R3/R4.
Questions

Frequently asked questions

01

What is the drift velocity of electrons and why is it so small yet currents are large?

Drift velocity is the small net average velocity (vd = eEτ/m) that electrons acquire opposite to the electric field, superposed on their large random thermal velocities. It is typically ~10⁻³ m/s for ordinary currents, yet currents can be large because the free electron number density in metals is enormous (~10²⁸–10²⁹ per m³), so even a tiny drift moves a great deal of charge per second.

02

What is the difference between EMF and terminal voltage of a cell?

EMF (ε) is the potential difference between the positive and negative terminals of a cell when no current flows (open circuit). Terminal voltage V = ε – Ir is the actual voltage across the terminals when current I flows, reduced by the voltage drop Ir across the cell's internal resistance r.

03

Under what conditions does Ohm's law fail?

Ohm's law fails when (a) V is not proportional to I (e.g., resistance increases with current), (b) the V–I relationship depends on the sign of V, as in a diode (rectifier), or (c) the relationship between V and I is non-unique, as seen in GaAs where multiple voltage values correspond to the same current.

04

Is the NCERT Class 12 Physics Chapter 3 PDF free to download?

Yes, the NCERT Class 12 Physics Part I Chapter 3 PDF is completely free to download on cbseprepmaster.com.

Keep learning

More chapters in Physics Part I

This is the complete Physics Part I Chapter 3 as published by NCERT — every diagram, solved example, and exercise included, free. Browse all CBSE Class 12 textbooks.

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